JP2017072339A - Air conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system having good energy efficiency.SOLUTION: An air conditioning system 1 includes: air conditioners 11, 12 in which cool temperature heating mediums M1, M2 are introduced; a radiation device 20 which is led-out from the air conditioners 11, 12, and in which a first medium temperature heating medium whose temperature has risen higher than the cool temperature is introduced directly or indirectly; and cooling devices 41, 42 which are led-out from the radiation device 20, and in which a second medium temperature heating medium whose temperature has risen higher than the first medium temperature is introduced directly or indirectly.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air conditioning system.

  Conventionally, an air conditioner in which a cooling coil, a heating coil, a fan, and the like are built in a casing is known (see Patent Document 1 below). During cooling, cooling water is circulated from the cooling source through the circulation line and supplied to the cooling coil. Further, air is sucked into the casing by the driven fan. The cooling coil exchanges heat between the cooling water and the sucked air so that cold air is blown into the room (see Patent Document 1 below).

  A radiation device including a radiation panel provided on the ceiling and a plurality of cold water pipes provided on the upper surface of the radiation panel is also known. In such a radiation device, the radiation panel is cooled by cooling water flowing through the cold water pipe, and the room is cooled by the radiation effect of the cooled radiation panel.

JP 2003-279096 A

  By the way, when the air conditioner and the radiating device described in Patent Document 1 are provided, it is necessary to manufacture the cooling water used in the air conditioner and the cooling water used in the radiating device with a cold heat source. For this reason, there exists a problem that the load of a cold-heat source will become large, and improving energy efficiency is desired.

  Then, this invention is made | formed in view of the said situation, and provides an energy efficient air conditioning system.

In order to achieve the above object, the present invention employs the following means.
That is, an air conditioning system according to the present invention includes an air conditioner into which a cold heat medium is introduced, and a first medium temperature heat medium that is derived from the air conditioner and has a temperature higher than the cold temperature, either directly or indirectly. A radiation device that is introduced; and a cooling device that is derived from the radiation device and into which the heat medium having a second intermediate temperature that is higher than the first intermediate temperature is directly or indirectly introduced. To do.

  In the air conditioning system configured as described above, the heat medium is introduced into the air conditioner at a low temperature. The heat medium that has risen from the cold temperature to become the first intermediate temperature and is derived from the air conditioner is directly or indirectly introduced into the radiation device. The heat medium that has risen from the first intermediate temperature to the second intermediate temperature and led out from the radiation device is cooled directly or indirectly by the cooling device. Therefore, in an air conditioning system having an air conditioner and a radiation device, the heat medium derived from the air conditioner can be used in the radiation device. For example, the heat medium used in the air conditioner and the radiation device is separately manufactured. Rather than energy efficiency.

  Further, in the air conditioning system according to the present invention, the cooling device includes a first cooling device that directly or indirectly introduces the first medium temperature heat medium and cools the heat medium to the cold temperature, A second cooling device that is directly or indirectly introduced to cool the heat medium to the first intermediate temperature, and is cooled to the cold temperature by the first cooling device. The heat medium is introduced directly or indirectly into the air conditioner, and the heat medium cooled to the first intermediate temperature by the second cooling device is introduced directly or indirectly into the radiation device. It is preferable that it is comprised.

  In the air conditioning system configured as described above, the first cooling device cools the heat medium that has been directly or indirectly introduced to the first intermediate temperature by the air conditioning device to a cold temperature. The heat medium having become cold is returned directly or indirectly to the air conditioner. The second cooling device cools the heat medium introduced directly or indirectly at the second intermediate temperature by the radiation device to the first intermediate temperature. The heat medium having reached the first intermediate temperature is returned directly or indirectly to the radiation device. In this way, the first cooling device cools the low-temperature heat medium, and the second cooling device cools the heat medium having a higher temperature than the heat medium cooled by the first cooling device. That is, the temperature range of the heat medium to be cooled is distinguished between the first cooling device and the second cooling device. Therefore, since the second cooling device only needs to cool the second medium temperature heat medium to the first medium temperature (which is higher in temperature than the cold temperature), it can be efficiently cooled and the required energy can be suppressed. Therefore, the load on the entire cooling device can be reduced.

  In the air conditioning system according to the present invention, the first medium temperature heat medium derived from the air conditioner and the second medium temperature heat medium derived from the radiation device are directly or indirectly introduced, A cooling tower capable of cooling the heat medium having the first intermediate temperature and the heat medium having the second intermediate temperature by heat exchange.

  In the air conditioning system configured as described above, the first medium temperature heat medium derived from the air conditioner and the second medium temperature heat medium derived from the radiation device are directly or indirectly introduced into the cooling tower. The cooling tower cools the first medium temperature heat medium and the second medium temperature heat medium by heat exchange with the atmosphere. Therefore, energy efficiency can be improved by using natural energy. In particular, since the heat medium having the second intermediate temperature is higher than the first intermediate temperature, it can be directly and efficiently cooled to the atmosphere, so that the running cost can be reduced and the amount of carbon dioxide emission can be reduced.

  In the air conditioning system according to the present invention, the air conditioning device may be installed in a first building, and the radiation device may be installed in a second building different from the first building.

  In the air conditioning system configured as described above, in the first building where the air conditioner is installed and the second building where the radiation device is installed, the heat medium derived from the air conditioner of the first building is used as the radiation device of the second building. Used in. Therefore, the surface utilization of the energy which shares a heat medium in a some building is attained, and energy efficiency can be improved locally.

  According to the air conditioning system of the present invention, energy efficiency can be improved.

It is the figure which showed typically the building where the air conditioning system which concerns on one Embodiment of this invention, and an air conditioning system are installed. It is a figure showing an air-conditioning system concerning one embodiment of the present invention. In an air-conditioning system concerning one embodiment of the present invention, it is a figure showing an example of a temperature change of a heat carrier. It is the figure which showed typically the building in which the air conditioning system which concerns on the modification of one Embodiment of this invention, and an air conditioning system are installed.

An air conditioning system according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram schematically illustrating an air conditioning system according to an embodiment of the present invention and a building in which the air conditioning system is installed. FIG. 2 is a diagram showing an air conditioning system according to an embodiment of the present invention.
As shown in FIG. 1, a first building B1 and a second building B2 to be air-conditioned and a heat source building B3 are installed adjacent to each other. As shown in FIG. 2, the air conditioning system 1 includes a plurality of air conditioners 11, 12, a radiation device 20, heat exchangers 31, 32, 33, cooling devices 41, 42, cooling towers 51, 52, It has.

  As shown in FIG. 1, in 1st building B1, the 2nd air conditioner 12 is installed in the low-rise floor, and the radiation apparatus 20 is installed in the middle-high floor. The first air conditioner 11 is installed in the second building B2. In the heat source building B3, heat exchangers 31, 32, 33, cooling devices 41, 42 and cooling towers 51, 52 are installed. In addition, the heat exchangers 31, 32, and 33 and the cooling towers 51 and 52 may be provided in the first building B1 and the second building B2.

  As shown in FIG. 2, the first air conditioner 11 includes, for example, a plurality of air conditioners (not shown; the same applies below) in which a fan coil (not shown; the same applies hereinafter) is built. A heat medium M1 such as cooling water is introduced. The 1st air conditioner 11 heat-exchanges the air and heat medium M1 which were taken in from the room with the fan coil, adjusts temperature and humidity, and blows air.

  The heat medium M <b> 1 whose temperature has been raised to the first intermediate temperature by heat exchange in the first air conditioner 11 is introduced into the third heat exchanger 33.

  The 2nd air conditioner 12 is comprised similarly to the 1st air conditioner 11, for example, and cold heat medium M2 is introduce | transduced. The second air conditioner 12 exchanges heat between the air taken in from the room with the fan coil and the heat medium M2, adjusts temperature and humidity, and blows air.

  The heat medium M <b> 2 whose heat has been exchanged by the second air conditioner 12 and whose temperature has risen to the first intermediate temperature is introduced into the first heat exchanger 31.

  The radiating device 20 includes a plurality of so-called radiant air conditioners, and a heat exchanger (not shown; the same applies hereinafter) into which the first medium temperature heat medium M3 is introduced, and a radiation panel (not shown; the same applies hereinafter). And a refrigerant pipe (not shown; the same applies below) through which a radiation side heat medium (not shown; the same applies below) is connected by connecting the heat exchanger and the radiation panel and exchanging heat with the heat medium M3 by the heat exchanger. ,have. The radiation-side heat medium that has been heat-exchanged with the heat medium M3 and cooled is circulated through the radiation panel, whereby cooling is performed.

  The heat medium M <b> 3 whose temperature has been increased from the first intermediate temperature to the second intermediate temperature after being heat-exchanged by the radiation device 20 is introduced into the second heat exchanger 32.

  The first heat exchanger 31 exchanges heat between the heat medium M2 introduced from the second air conditioner 12 and the heat medium M11. The heat medium M <b> 2 has its temperature lowered from the first intermediate temperature to the cold temperature by the heat exchange in the first heat exchanger 31, and is returned to the second air conditioner 12. On the other hand, the temperature of the heat medium M11 rises from the cold temperature to the first medium temperature by heat exchange in the first heat exchanger 31, and part of the heat medium M11 is introduced into the first cooling device 41, and the rest is the third together with the heat medium M1. It is introduced into the heat exchanger 33.

  The second heat exchanger 32 exchanges heat between the heat medium M3 and the heat medium M12 introduced from the radiation device 20. The heat medium M <b> 3 has its temperature lowered from the second intermediate temperature to the first intermediate temperature by the heat exchange in the second heat exchanger 32, and is returned to the radiation device 20. On the other hand, the temperature of the heat medium M12 rises from the first intermediate temperature to the second intermediate temperature by heat exchange in the second heat exchanger 32, and part of the heat medium M12 is introduced into the third heat exchanger 33, and the rest is the second cooling. Introduced into the device 42.

  The third heat exchanger 33 includes the heat medium M12 introduced from the second heat exchanger 32, the heat medium M1 introduced from the first air conditioner 11, and the heat medium M11 introduced from the first heat exchanger 31. Exchange heat. The heat medium M <b> 12 has its temperature lowered from the second intermediate temperature to the first intermediate temperature by the heat exchange in the third heat exchanger 33, and is returned to the second heat exchanger 32. On the other hand, the heat mediums M <b> 1 and M <b> 11 slightly rise in temperature due to heat exchange in the third heat exchanger 33 and are introduced into the first cooling device 41. The temperature of the heat medium M1, M11 whose temperature has risen does not rise to the second intermediate temperature, but is within a predetermined temperature range of the first intermediate temperature.

  The first cooling tower 51 cools the first medium temperature heat medium M <b> 11 introduced from the first heat exchanger 31 and the first medium temperature heat medium M <b> 1, M <b> 11 introduced from the third heat exchanger 33. The heat mediums M1 and M11 are directly cooled by free cooling for heat exchange with the atmosphere. When the heat mediums M1 and M11 are cooled to a cold temperature, they are returned to the first heat exchanger 31 and the first air conditioner 11 via pipes (not shown), respectively. On the other hand, the heat mediums M1 and M11 are introduced into the first cooling device 41 if they are not cooled to a cold temperature. Alternatively, the heat mediums M1 and M11 may be directly introduced into the first cooling device 41 from the first heat exchanger 31 and the third heat exchanger 33 without passing through the first cooling tower 51. .

  The second cooling tower 52 cools the second medium temperature heat medium M12 introduced from the second heat exchanger 32 to the first medium temperature. The heat medium M12 is directly cooled by free cooling for heat exchange with the atmosphere. When the heat medium M12 is cooled to the first intermediate temperature, it is returned to the second heat exchanger 32 via a pipe line (not shown). On the other hand, if the heat medium M12 is not cooled to the first intermediate temperature, it is introduced into the second cooling device. Alternatively, the heat medium M12 may be directly introduced into the second cooling device 42 from the second heat exchanger 32 without passing through the second cooling tower 52.

  The first cooling device 41 and the second cooling device 42 are, for example, INV turbo chillers. The first cooling device 41 cools the heat mediums M1 and M11 to a cold temperature. The heat mediums M11 and M1 cooled by the first cooling device 41 are returned to the first heat exchanger 31 and the first air conditioner 11, respectively.

  The second cooling device 42 cools the heat medium M12 to the first intermediate temperature. The heat medium M12 cooled by the second cooling device 42 is returned to the second heat exchanger 32.

Next, an example of the temperature change of the heat medium in the air conditioning system will be described with reference to FIG.
FIG. 3 is a diagram illustrating an example of a temperature change of the heat medium in the air conditioning system.
As shown in FIG. 3, the heat medium M <b> 1 cooled to 7 ° C. by the first cooling device 41 or the first cooling tower 51 is introduced into the first air conditioner 11. The heat medium M <b> 1 rises to 14 ° C. by heat exchange in the first air conditioner 11 and is introduced into the third heat exchanger 33.

  The heat medium M1 heat-exchanged with the heat medium M12 in the third heat exchanger 33 rises to 17 ° C. and is introduced into the first cooling tower 51. On the other hand, the temperature of the heat medium M12 exchanged with the heat medium M1 by the third heat exchanger 33 is reduced from 19 ° C. to 14 ° C. and returned to the second heat exchanger 32.

  The temperature of the heat medium M3 exchanged with the heat medium M12 by the second heat exchanger 32 is lowered to 14 ° C. and is introduced into the radiation device 20. On the other hand, the temperature of the heat medium M12 exchanged with the heat medium M3 in the second heat exchanger 32 rises to 19 ° C. and is introduced into the third heat exchanger 33 and the second cooling tower 52.

  The heat medium M <b> 3 introduced from the second heat exchanger 32 to the radiating device 20 rises to 19 ° C. due to heat exchange in the radiating device 20 and is introduced into the second heat exchanger 32.

  On the other hand, a heat medium M2 of 7 ° C. is introduced into the second air conditioner 12 from the first heat exchanger 31. The heat medium M <b> 2 rises to 14 ° C. due to heat exchange in the second air conditioner 12 and is introduced into the first heat exchanger 31.

  The heat medium M2 exchanged with the heat medium M11 in the first heat exchanger 31 is lowered to 7 ° C. and returned to the second air conditioner 12. On the other hand, the heat medium M11 heat-exchanged with the heat medium M2 in the first heat exchanger 31 rises from 7 ° C. to 14 ° C., and a part thereof is introduced into the first cooling tower 51, and the rest is the third heat exchange. Returned to vessel 33.

  The heat media M11 and M1 introduced from the first heat exchanger 31 and the third heat exchanger 33 to the first cooling tower 51 are directly cooled by free cooling. For example, when it is cooled to 7 ° C., it is returned to the first heat exchanger 31 and the first air conditioner 11. On the other hand, the heat mediums M11 and M1 are introduced into the first cooling device 41 when they are not cooled to 7 ° C. The heat mediums M11 and M1 cooled to 7 ° C. by the first cooling device 41 are returned to the first heat exchanger 31 and the first air conditioner 11.

  The heat medium M12 introduced from the second heat exchanger 32 to the second cooling tower 52 is directly cooled by free cooling. For example, when it is cooled to 14 ° C., it is returned to the second heat exchanger 32. On the other hand, the heat medium M12 is introduced into the second cooling device 42 when it is not cooled to 14 ° C. The heat medium M12 cooled to 14 ° C. by the second cooling device 42 is returned to the second heat exchanger 32.

In the air conditioning system configured as described above, the heat medium M1 is introduced into the first air conditioner 11 at a low temperature. The heat medium M <b> 1 derived from the first air conditioner 11 with the temperature rising from the cold temperature to become the first intermediate temperature is heat-exchanged with the heat medium M <b> 12 by the third heat exchanger 33. The heat medium M12 that has reached the first intermediate temperature by the heat exchange is heat-exchanged with the heat medium M3 by the second heat exchanger 32. The heat medium M3 that has reached the first intermediate temperature due to the heat exchange is introduced into the radiation device 20. That is, the heat medium M <b> 1 derived from the first air conditioner 11 at the first intermediate temperature is indirectly introduced into the radiation device 20.
Further, the heat medium M2 is introduced into the second air conditioner 12 at a low temperature. The heat medium M2 that has risen from the cold temperature to the first intermediate temperature and is derived from the second air conditioner 12 is heat-exchanged with the heat medium M11 by the first heat exchanger 31. A part of the heat medium M11 having the first intermediate temperature due to the heat exchange is heat-exchanged with the heat medium M12 in the third heat exchanger 33. The heat medium M12 that has reached the first intermediate temperature by the heat exchange is heat-exchanged with the heat medium M3 by the second heat exchanger 32. The heat medium M3 that has reached the first intermediate temperature due to the heat exchange is introduced into the radiation device 20. That is, the heat medium M <b> 2 derived from the second air conditioner 12 at the first intermediate temperature is indirectly introduced into the radiation device 20.
Therefore, in the air conditioning system 1 in which the first air conditioner 11, the second air conditioner 12, and the radiation device 20 are installed, the heat medium M <b> 1, M <b> 2 derived from the first air conditioner 11 and the second air conditioner 12 is the radiation device 20. Since it can be used, for example, it is possible to improve the energy efficiency as compared to separately manufacturing the heat medium used in the air conditioner and the radiation device.

  Moreover, the 2nd air conditioning apparatus 12 and the radiation apparatus 20 are installed in 1st building B1, and the 1st air conditioning apparatus 11 is installed in 2nd building B2. And the heat medium M2 derived | led-out from the 2nd air conditioning apparatus 12 of 1st building B1 and the heat medium M1 derived | led-out from the 1st air conditioning apparatus 11 of 2nd building B2 are indirectly radiating apparatus 20 of 1st building B1. Used in. Therefore, the surface utilization of the energy which shares a heat medium in a some building is attained, and energy efficiency can be improved locally. Compared to a general district heating and cooling system, the total energy efficiency (COP) can be improved by about 50%.

In addition, the first cooling device 41 is indirectly introduced with the heat medium M <b> 1 having the first intermediate temperature in the first air conditioner 11 through the third heat exchanger 33, and the second air conditioner 12 The heat medium M <b> 2 having a medium temperature is introduced as the heat medium M <b> 11 through the first heat exchanger 31. The first cooling device 41 cools the heat mediums M1 and M11 to a cold temperature. The heat medium M1 that has become cold is returned to the first air conditioner 11, and the heat medium M11 is returned to the second air conditioner 12 as the heat medium M2 via the first heat exchanger 31.
The second cooling device 42 is introduced with the heat medium M3 that has reached the second intermediate temperature by the radiation device 20 as the heat medium M12 via the second heat exchanger 32. The second cooling device 42 cools the heat medium M12 to the first intermediate temperature. The heat medium M12 having reached the first intermediate temperature is returned to the radiation device 20 as the heat medium M3 through the second heat exchanger M32.
That is, the first cooling device 41 cools the low-temperature (for example, 14 to 17 ° C.) heat media M1 and M11, and the second cooling device 42 has a higher temperature than the heat media M1 and M11 cooled by the first cooling device 41. (For example, 19 degreeC) The heat medium M12 is cooled. Thus, the first cooling device 41 and the second cooling device 42 distinguish the temperature zones of the heat medium to be cooled. Therefore, the second cooling device 42 only needs to cool the heat medium having the second medium temperature (for example, 19 ° C.) to the first medium temperature (for example, 14 ° C., which is higher in temperature than the cold temperature). , Can reduce the required energy. Therefore, the load on the entire cooling device can be reduced.

  Moreover, the heat medium M1, M2, M3 derived from the first air conditioner 11, the second air conditioner 12, and the radiation device 20 is introduced into the first cooling tower 51 and the second cooling tower 52 as the heat medium M1, M11, M12. Is done. The 1st cooling tower 51 and the 2nd cooling tower 52 cool heat medium M1, M11, M12 by heat exchange with air | atmosphere. Therefore, energy efficiency can be improved by using natural energy. Further, the temperature of the heat medium M12 introduced into the second cooling tower 52 is 19 ° C., and it may be 14 ° C. when derived, and both are relatively high temperatures. Free cooling can be performed over a long period of the month. Therefore, it is possible to reduce running costs and carbon dioxide emissions.

(Modification)
Next, a modification of the embodiment described above will be described mainly with reference to FIG.
In the following modifications, the same members as those used in the above-described embodiment are denoted by the same reference numerals, and the description thereof is omitted.
FIG. 4 is a diagram schematically showing an air conditioning system and a building where the air conditioning system is installed according to a modification of the embodiment of the present invention.
As shown in FIG. 4, in the air conditioning system 2, the heat medium M <b> 2 used in the second air conditioner 12 of the first building B <b> 1 is directly introduced into the radiation device 20. In addition, the heat medium M1 used in the first air conditioner 11 of the second building B2 is directly introduced into the radiation device 20. If the pressure, temperature, etc. of the circulating heat mediums M1, M2 etc. can be adjusted, the heat mediums M1, M2 used in the first air conditioner 11 and the second air conditioner 12 in this way are directly applied to the radiation device 20. May be introduced.

  The various shapes and combinations of the constituent members shown in the above-described embodiments are merely examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

  For example, in the embodiment shown above, in the first building B1, the second air conditioner 12 is installed on the lower floor and the radiation device 20 is installed on the middle and upper floors, but the present invention is not limited to this, and the air conditioner The floor where the radiation device is installed can be selected as appropriate. Further, an air conditioner may be provided along with the radiation device 20 on the middle and high floors. In this case, it is preferable that a heat exchanger is separately installed so that the heat medium exchanged with the air conditioner is directly or indirectly introduced into the radiation device 20.

  Moreover, in embodiment shown above, although an air conditioner is comprised from the 2nd air conditioner 12 installed in 1st building B1, and the 1st air conditioner 11 installed in 2nd building B2, this invention is It is not limited to this. The second air conditioner 12 may not be installed in the first building B1, and only the radiation device 20 may be installed. Alternatively, the second air conditioner 12 and the radiation device 20 may be installed in the first building B1 without providing the second building B2, and the air conditioning system 1 may be established in the first building B1. In this case, energy efficiency can be improved in the first building B1 alone.

DESCRIPTION OF SYMBOLS 1, 2 ... Air conditioning system 11 ... 1st air conditioner 12 ... 2nd air conditioner 20 ... Radiation apparatus 31 ... 1st heat exchanger 32 ... 2nd heat exchanger 33 ... 3rd heat exchanger 41 ... 1st cooling device 42 ... 2nd cooling device 51 ... 1st cooling tower 52 ... 2nd cooling tower B1 ... 1st building B2 ... 2nd building

Claims (4)

An air conditioner into which a cold heat medium is introduced;
A radiation device that is derived from the air conditioner and into which the heat medium having a first intermediate temperature that is higher than the cold temperature is directly or indirectly introduced;
An air conditioning system comprising: a cooling device that is derived from the radiation device and into which the heat medium having a second intermediate temperature that is higher than the first intermediate temperature is introduced directly or indirectly. The cooling device is
A first cooling device in which the heat medium having the first medium temperature is directly or indirectly introduced and cools the heat medium to the cold temperature;
A second cooling device that directly or indirectly introduces the heat medium at the second medium temperature and cools the heat medium to the first medium temperature;
The heat medium cooled to the cold temperature by the first cooling device is directly or indirectly introduced into the air conditioner,
The air conditioner according to claim 1, wherein the heat medium cooled to the first intermediate temperature by the second cooling device is configured to be directly or indirectly introduced into the radiation device. system.   The first medium temperature heating medium derived from the air conditioner and the second medium temperature heating medium derived from the radiation device are introduced directly or indirectly, and the first medium temperature is obtained by heat exchange with the atmosphere. The air conditioning system according to claim 1 or 2, further comprising a cooling tower capable of cooling the heat medium and the second medium temperature heat medium. The air conditioner is installed in a first building,
4. The air conditioning system according to claim 1, wherein the radiation device is installed in a second building different from the first building. 5.

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